AbstractIn this paper, we discuss the time-domain metamaterial Maxwell’s equations. One major contribution of this paper is that after some effort we find that the metamaterial Maxwell’s equations can be beautifully reduced to a vector wave integro-differential equation involving just one unknown, which is quite similar to that obtained from the standard Maxwell’s equations in vacuum. Then we study the existence and uniqueness of this new modeling equations, and propose a fully-discrete finite element method to solve this model. Numerical results justifying our analysis are presented. This discovery shall make simulation of metamaterials much more efficient than the previous works
The Perfectly Matched Layer (PML) technique is an effective tool introduced by B´erenger [13] to red...
We present the solution of multilayer metamaterial (MM) structures containing large numbers of unit ...
Graduation date: 2016In this thesis we construct compatible discretizations of Maxwell's equations. ...
AbstractIn this paper, we discuss the time-domain metamaterial Maxwell’s equations. One major contri...
AbstractThe discontinuous Galerkin method has proved to be an accurate and efficient way to numerica...
In this paper, we develop a nodal discontinuous Galerkin method for solving the time-dependent Maxwe...
Discontinuous Galerkin Finite Element Method (DG-FEM) has been further developed in this dissertatio...
In this paper, we discuss a time domain finite element method for the approximate solution of Maxwel...
We have constructed a new finite-difference time-domain (FDTD) method in this project. Our new algor...
AbstractIn this paper, we develop both semi-discrete and fully discrete mixed finite element methods...
Purpose \u2013 To provide sufficient conditions for existence, uniqueness and finite element approxi...
Existence and uniqueness of the solution of time-harmonic electromagnetic boundary value problems is...
Metasurfaces are thin metamaterial layers characterized by unusual dispersion properties of surface/...
This dissertation investigates three different mathematical models based on the time domain Maxwell\...
We consider time domain formulations of Maxwell's equations for the Lorentz model for metamaterials....
The Perfectly Matched Layer (PML) technique is an effective tool introduced by B´erenger [13] to red...
We present the solution of multilayer metamaterial (MM) structures containing large numbers of unit ...
Graduation date: 2016In this thesis we construct compatible discretizations of Maxwell's equations. ...
AbstractIn this paper, we discuss the time-domain metamaterial Maxwell’s equations. One major contri...
AbstractThe discontinuous Galerkin method has proved to be an accurate and efficient way to numerica...
In this paper, we develop a nodal discontinuous Galerkin method for solving the time-dependent Maxwe...
Discontinuous Galerkin Finite Element Method (DG-FEM) has been further developed in this dissertatio...
In this paper, we discuss a time domain finite element method for the approximate solution of Maxwel...
We have constructed a new finite-difference time-domain (FDTD) method in this project. Our new algor...
AbstractIn this paper, we develop both semi-discrete and fully discrete mixed finite element methods...
Purpose \u2013 To provide sufficient conditions for existence, uniqueness and finite element approxi...
Existence and uniqueness of the solution of time-harmonic electromagnetic boundary value problems is...
Metasurfaces are thin metamaterial layers characterized by unusual dispersion properties of surface/...
This dissertation investigates three different mathematical models based on the time domain Maxwell\...
We consider time domain formulations of Maxwell's equations for the Lorentz model for metamaterials....
The Perfectly Matched Layer (PML) technique is an effective tool introduced by B´erenger [13] to red...
We present the solution of multilayer metamaterial (MM) structures containing large numbers of unit ...
Graduation date: 2016In this thesis we construct compatible discretizations of Maxwell's equations. ...